Device, system and method for measuring angle adjustment of a hookspanner wrench to accurately tighten a bearing onto a shaft having a threaded and a tapered portion

ABSTRACT

A system for measuring angle adjustment of a hookspanner wrench to accurately tighten a bearing onto a shaft having a threaded and tapered portion. The system including a device providing a hookspanner wrench having a lever arm and an engaging portion, the engaging portion of the hookspanner wrench configured to engage a bearing locking nut, the lever arm configured to mount a storage clamping device fixed thereto, a smartphone secured in place by the storage clamping device, and a specialized application stored on the smartphone that provides a built-in inclinometer and look up data tables. A method for measuring angle adjustment of a hookspanner wrench to accurately tighten a bearing onto a shaft having a threaded and tapered portion as well.

TECHNOLOGICAL FIELD

The present invention relates to the field of measuring angle movement of a hookspanner wrench. The invention relates more particularly to the field of measuring angle adjustment of a hookspanner wrench to accurately tighten a bearing onto a shaft having a threaded and tapered portion utilizing an application on a smartphone mounted to the hookspanner wrench.

BACKGROUND OF THE INVENTION

The current technology for accomplishing the function of the present invention provides making an inaccurate manual angle marking on the hookspanner wrench and by making another inaccurate manual reference mark on the application/shaft. Then, turning the hookspanner wrench to until the two manually referenced marks blindly match up.

SUMMARY OF THE INVENTION

According to a first aspect, exemplary embodiments relate to a device for measuring angle adjustment of a hookspanner wrench to accurately tighten a bearing onto a shaft having a threaded and tapered portion. The device provides a hookspanner wrench having a lever arm and an engaging portion, the engaging portion configured to engage a bearing locking nut, the lever arm configured to mount a storage clamping device fixed thereto, a smartphone secured in place by the storage clamping device, and a specialized application or executable program stored on the smartphone that provides a built-in inclinometer and look up data tables.

In a second aspect of the above exemplary embodiment the look up data tables display a correct bearing locking nut drive up angle based on a bearing type inputted into the smartphone.

In a third aspect of the above exemplary embodiment when a force is applied to an outer end of the lever arm and the hookspanner wrench begins to rotate the bearing locking nut, and wherein the inclinometer responds in real time and displays an updated locking nut drive up angle position.

In a further aspect of the above exemplary embodiment the application of force applied to the lever arm is stopped when the correct mounting angle/drive up position is indicated as being obtained on the inclinometer.

In a further aspect of the above exemplary embodiment the storage clamping device provides an adjustment mechanism that enables installation of the smartphone in both a horizontal and vertical direction to facilitate different sized smartphones.

In a further aspect of the above exemplary embodiment one of an angle, a number, and a color is displayed on the inclinometer to indicate the mounting angle/drive up position obtained.

In a further aspect of the above exemplary embodiment a Full Qwerty Keypad is provided for entering bearing type information that identifies a correct locking nut drive up angle on at least one display of the computing device.

According to a second aspect, exemplary embodiments relate to a system for measuring angle adjustment of a hookspanner wrench to accurately tighten a bearing onto a shaft having a threaded and tapered portion. The system includes a device providing a hookspanner wrench having a lever arm and an engaging portion, the engaging portion of the hookspanner wrench configured to engage a bearing locking nut, the lever arm configured to mount a storage clamping device fixed thereto, a smartphone secured in place by the storage clamping device, and a specialized application stored on the smartphone that provides a built-in inclinometer and look up data tables, the bearing having an inner race and a tapered bore being mounted over an outer unthreaded portion of the tapered shaft, the bearing locking nut having a threaded inner portion and screwed onto a threaded portion of the tapered shaft, the bearing locking nut screwed onto the threaded portion of the tapered shaft until an inner side of the locking nut and an outer side of the bearing inner race contact each other, an interlocking arrangement providing a meshing grip between the hookspanner wrench and the locking nut, information regarding a type of bearing to be secured being entered into the smartphone, and wherein in response, a correct mounting angle/drive up position of the locking nut is displayed on the built-in inclinometer, a force F applied to the lever portion of the hookspanner wrench causes the hookspanner wrench to rotate while the mounting angle/drive up position is monitored against what is displayed on the inclinometer and wherein the application of force to the lever portion is stopped when the correct mounting angle/drive up position is indicated as being obtained on the inclinometer.

In a further aspect of the above exemplary embodiment the contact between an inner side of the locking nut and an outer side of the bearing inner race is a metal to metal contact.

According to a third aspect, exemplary embodiments relate a method of measuring angle adjustment of a hookspanner wrench to accurately secure a bearing onto a shaft, the shaft having a threaded and tapered portion. The method includes sliding the bearing onto the tapered portion of the shaft, screwing a locking nut onto the threaded portion of the shaft until an inner side of the locking nut and an outer side of the bearing inner race contact each other, removing the locking nut off of the adapter sleeve with the hookspanner wrench, placing a spacer over the threaded portion of the shaft and up against the bearing, placing a lock washer over the threaded portion of the shaft and up against the spacer, attaching the hookspanner wrench onto the locking nut, providing a mounting device for a portable computing device disposed on a lever portion of the hookspanner wrench, attaching the portable computing device onto the mounting device, the computing device having a software application that includes a built-in inclinometer, initializing the software application that includes the built-in inclinometer, inputting identifying information into a display disposed on the computing device regarding a bearing type to be tightened, displaying a correct mounting angle/drive up position of the component on the built-in inclinometer, applying force to the lever portion and rotating the hookspanner wrench while monitoring the mounting angle/drive up position against what is displayed on the inclinometer, and stopping the application of force to the lever portion when the correct mounting angle/drive up position is indicated as being obtained on the inclinometer,

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention and its advantages will be better understood by studying the detailed description of specific embodiments given by way of non-limiting examples and illustrated by the appended drawings on which:

FIG. 1 is an elevated perspective view of a system for measuring angle adjustment of a hookspanner wrench according to an embodiment of the present invention;

FIG. 2 is an elevated perspective view of a device according to the system of FIG. 1;

FIG. 3 is an elevated perspective view of a locking nut, bearing and mounting shaft according to the system of FIG. 1;

FIG. 4 is a cross-sectional view of the locking nut, shaft and bearing according to the system of FIG. 1;

FIG. 5 is an elevated perspective view of a system that includes a device, locking nut, mounting shaft and bearing shown disposed on a tapered portion of the shaft according to the system of FIG. 1;

FIG. 6 is a cross-sectional view of the locking nut and bearing being installed onto the shaft according to the embodiment of FIG. 1;

FIG. 7 is a cross-sectional view of the locking nut, lock washer, spacer, and bearing being installed onto the shaft according to an embodiment of the invention;

FIG. 8 is an elevated perspective view of the locking nut, lock washer, spacer, and bearing being installed onto the shaft according to an embodiment of the invention;

FIG. 9 is a cross-sectional view of the locking nut, lock washer, spacer, and bearing installed onto the shaft according to an embodiment of the invention;

FIG. 10 is an elevated perspective view of the system for measuring angle adjustment of a hookspanner wrench with the bearing, spacer, lock washer and locking nut in the process of being secured according to an embodiment of the present invention;

FIGS. 11A, 11B and 11C are plan views of the various options for displaying the inclinometer application on a portable computing device according to an embodiment of the present invention;

FIG. 12 is a side plan view of the system for measuring angle adjustment of a hookspanner wrench showing the inclinometer application running in real time on the portable computing device according to an embodiment of the present invention;

FIG. 13 is a further side plan view of the system for measuring angle adjustment of a hookspanner wrench showing the inclinometer application running in real time and showing that a stop position has been reached according to an embodiment of the present invention; and

FIGS. 14A-14B show the method steps for carrying out the function of the system according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

The following detailed description is merely exemplary in nature and is not intended to limit the described embodiments or the application and uses of the described embodiments. As used herein, the word “exemplary” or “illustrative” means “serving as an example, instance, or illustration.” Any implementation described herein as “exemplary” or “illustrative” is not necessarily to be construed as preferred or advantageous over other implementations. All of the implementations described below are exemplary implementations provided to enable persons skilled in the art to make or use the embodiments of the disclosure and are not intended to limit the scope of the disclosure, which is defined by the claims.

For purposes of description herein, the terms “inward,” “outward,” “upper,” “lower,” “left,” “rear,” “right,” “front,” “vertical,” “horizontal,” and derivatives thereof shall relate to the invention as oriented in FIG. 1. Furthermore, there is no intention to be bound by any expressed or implied theory presented in the preceding technical field, background, brief summary or the following detailed description. It is also to be understood that the specific devices and processes illustrated in the attached drawings, and described in the following specification, are simply exemplary embodiments of the inventive concepts defined in the appended claims. Hence, specific dimensions and other physical characteristics relating to the embodiments disclosed herein are not to be considered as limiting, unless the claims expressly state otherwise.

System and Device

There is shown in FIG. 1 a system 100 for measuring angle adjustment of a hookspanner wrench 10 to accurately tighten a bearing 20 onto a shaft 30. The shaft 30 may provide a threaded portion 40 and a tapered portion 47. The threaded portion 40 includes a slot 49, the purpose of which will be disclosed later in this description. The system 100 further provides a locking nut 50 that is to be tightened by the hookspanner wrench 10.

Now referring to FIGS. 1-2, the system 100 may also provide a device 110. The device 110 by itself, is illustrated in FIG. 2. The device 110 provides the hookspanner wrench 10, which includes a lever arm 15 and an engaging portion 17. The engaging portion 17 of the hookspanner wrench 10 is configured to engage at least four indentations 52 disposed on an outer surface of the bearing locking nut 50. The engaging portion 17 includes a projection 19 that interlocks with one of the at least four indentations 52. As such, this interlocking arrangement provides a latching grip between the hookspanner wrench 10 and the locking nut 50.

The lever arm 15 is configured to mount a storage clamping device 60 fixed thereto. A portable communications device or smartphone 70 is secured in place by the storage clamping device 60. The storage clamping device 60 provides a sliding adjustment mechanism. The sliding adjustment mechanism enables installation of the smartphone in both a horizontal and vertical direction (as depicted by the arrows) to facilitate different sized smartphones.

An Application (App) 72 or Mobile application software 72 that is designed to run on smartphones and other mobile devices is stored in a memory 932 (See FIG. 11) of the smartphone 70. The smartphone may also provide a microprocessor 932 that works together with the memory 930 in order carry out the functions of the App. Most importantly to the present invention, the App 72 provides a built-in inclinometer 90 and look up data tables 74 that are shown on a display 77 (See FIGS. 14A, 14B and 14C). The look up data tables 74 display a correct bearing to locking nut drive up angle based on a bearing type that is inputted into the smartphone.

Referring now to FIGS. 3-5, the bearing 20 has an inner race 21 that includes a tapered bore 22. During assembly, the tapered bore 22 of the bearing 20 is gently slid up over the threaded portion 40 of the shaft 30 and rests on the tapered portion 47 of the shaft 30. The bearing locking nut 50 has a threaded inner portion 54. The threaded inner portion 54 of the locking nut 50 mates with the threaded portion 40 of the shaft 30.

The bearing locking nut 50 is screwed onto the threaded portion 40 of the shaft 30 until an inner side 56 of the locking nut 50 and an outer side of the bearing inner race 24 contact each other. The locking nut 50 is “hand tightened” until the inner side 56 of the locking nut 56 and outer side of the bearing inner race just begin to make contact and only a very light force is created driving up against the bearing. In addition, depending on the materials of construction, the contact between the inner side 56 of the locking nut 50 and the outer side of the bearing inner race 24 may provide a metal to metal contact.

Once the inner side 56 of the locking nut 50 is hand tightened up against the outer side of bearing inner race 24 the location of the bearing 20 on the tapered portion 47 of the shaft 30 is initially set. The assembly can be seen in the cross-section illustrated in FIG. 6.

At this point, the locking nut 50 is now removed so that a spacer 92 and a lock washer 82 can be inserted onto the shaft and gently pressed up against the inner race 24 of the bearing 20. See FIGS. 6-9. A tab 84 of the lock washer 82 that projects radially inward engages the recessed slot 49 of the threaded portion 40 of the shaft. This engagement prevents the lock washer from spinning and functions to secure the locking nut to the lock washer when tightened. Now that the spacer and lock washer are installed, the locking nut is manually screwed onto the threaded portion of the shaft. Once again, the locking nut 50 is “hand tightened” until the inner side 56 of the locking nut 56 and outer side of the bearing inner race just begin to make contact and only a very light force between the two is created driving up against the bearing.

Now that the bearing with the tapered inner race is initially set onto the tapered portion of the shaft and the spacer, lock washer and locking nut are hand tightened in place, the device 110 for accurately securing the bearing onto the shaft as shown in FIG. 10 is ready to be utilized.

Now referring to FIGS. 10-13, there is shown a Full Qwerty Keypad FQK for entering bearing type information. The bearing type information identifies a correct locking nut drive up angle 90. The correct locking nut drive up angle 90 is shown on the display 77 of the computing device 70. See specifically FIGS. 11A, 11B and 11C. The look up data tables 74 display a correct bearing to locking nut drive up angle based on a bearing type that is inputted into the smartphone. In response, a correct mounting angle/drive up position of the locking nut 50 is displayed on the built-in inclinometer 90.

When a force F is applied to the lever portion 15 of the hookspanner wrench, the force causes the hookspanner wrench to rotate. When the force F is applied to an outer end of the lever arm the hookspanner wrench begins to rotate the bearing locking nut. As the wrench begins to rotate, the inclinometer responds in real time and displays an updated locking nut drive up angle position in a clockwise fashion. Accordingly, while rotating the mounting angle/drive up position is monitored against what is displayed on the inclinometer 90. The application of force F to the lever portion is stopped when the correct mounting angle/drive up position is indicated as being obtained on the inclinometer.

The correct mounting angle/drive up position can be indicated in multiple ways. First, a graph of the drive up angle can be displayed as illustrated in FIG. 11B. Here, an initial Start point is indicated and as the spanner wrench is rotated, the Current angle α changes. The drive up angle is reached when the arrow indicates the Goal is reached.

In the configuration shown in FIG. 11C, the Start or Current angle may be displayed in an upper portion 92 of the inclinometer 90 and the Goal angle may be displayed in a lower portion 94 of the inclinometer 90.

In the configuration shown in FIGS. 12-13, the Start or Current angle may be displayed as a vertical arrow extending upwards on the display of the inclinometer. Here, a color is displayed on the inclinometer 90 to indicate the present mounting angle/drive up position. For example, the section on the inclinometer that is colored Green may indicate “continue rotating the hookspanner wrench”. The Yellow section may indicate “you are getting close to the desired drive up angle Goal” and the Red section may indicate the Goal has been obtained”. As such, the vertical arrow stays extending upwards and the sections of color move towards the Goal as the spanner wrench is rotated.

Method

A method 200 of measuring angle adjustment of the hookspanner wrench to accurately secure the bearing onto the shaft, the shaft having tapered and threaded portions will now be disclosed.

In a first step 210 the method includes sliding the bearing onto the tapered portion of the shaft. Here, the bearing is gently slid up onto the tapered portion of the shaft. This opposed to being rammed in place.

In a second step 220 the method comprises screwing a locking nut onto the threaded portion of the shaft. The locking nut is screwed onto the threaded portion of the shaft until the inner side of the locking nut and the outer side of the bearing inner race begin to contact each other.

In a next step 230 the method provides removing the locking nut off of the threaded portion. This is done in anticipation of s next step 240 that provides placing the spacer over the threaded portion of the shaft and up against the bearing. In addition, the method provides placing the lock washer over the threaded portion of the shaft and up against the spacer in a step 250.

In a following step 260 the method provides attaching the hookspanner wrench onto the locking nut. As previously disclosed, the engaging portion of the hookspanner wrench is configured to engage the at least four indentations disposed on the outer surface of the bearing locking nut. The engaging portion includes a projection that interlocks with one of the at least four indentations. As such, this interlocking arrangement provides a latching grip between the hookspanner wrench and the locking nut.

The method then includes a step 270 of providing the mounting device for the portable computing device, the mounting device being disposed on the lever portion of the hookspanner wrench.

The method then calls for a step 280 of attaching the portable computing device onto the mounting device, the computing device having a software application that includes a built-in inclinometer.

The method further includes a step 290 of initializing the software application that includes the built-in inclinometer.

Inputting identifying information into a display disposed on the computing device regarding a bearing type to be tightened is carried out in a step 300.

The method entails a step 310 of displaying a correct mounting angle/drive up position of the component on the built-in inclinometer.

The method includes a step 320 of applying force F to the lever portion and rotating the hookspanner wrench while simultaneously monitoring the mounting angle/drive up position displayed on the inclinometer.

Finally, the method provides a step 330 of stopping the application of force F to the lever portion when the correct mounting angle/drive up position is indicated as being obtained on the inclinometer. As such, when the correct mounting angle/drive up position is shown on the display, the method is completed and the force is stopped.

Since many modifications, variations, and changes in detail can be made to the described preferred embodiments and methods of the invention, it is intended that all matters in the foregoing description and shown in the accompanying drawings be interpreted as illustrative and not in a limiting sense. Thus, the scope of the invention should be determined by the appended claims and their legal equivalence. 

The invention claimed is:
 1. A system for measuring angle adjustment of a hookspanner wrench to accurately tighten a bearing onto a shaft having a threaded and tapered portion, the system comprising: a hookspanner wrench having a lever arm and an engaging portion, the engaging portion configured to engage a bearing locking nut, a storage clamping device comprising a clamp, the storage clamping device being positioned on the lever arm, a smartphone secured in place by the clamp of the storage clamping device, and a specialized application stored on the smartphone that provides a built-in inclinometer and look up data tables.
 2. The system for measuring angle adjustment of a hookspanner wrench according to claim 1, wherein the look up data tables display a correct bearing locking nut drive up angle based on a bearing type inputted into the smartphone.
 3. The system for measuring angle adjustment of a hookspanner wrench according to claim 2, wherein when a force is applied to an outer end of the lever arm and the hookspanner wrench begins to rotate the bearing locking nut, and wherein the inclinometer responds in real time and displays an updated locking nut drive up angle position.
 4. The system for measuring angle adjustment of a hookspanner wrench according to claim 3, wherein the application of force applied to the lever arm is stopped when the correct mounting angle/drive up position is indicated as being obtained on the inclinometer.
 5. The system for measuring angle adjustment of a hookspanner wrench according to claim 1, wherein the storage clamping device provides an adjustment mechanism that enables installation of the smartphone in both a horizontal and vertical direction to facilitate different sized smartphones.
 6. The system for measuring angle adjustment of a hookspanner wrench according to claim 1, wherein one of an angle, a number, and a color is displayed on the inclinometer to indicate the mounting angle/drive up position has been obtained.
 7. The system for measuring angle adjustment of a hookspanner wrench according to claim 1, further comprises a Full Qwerty Keypad for entering bearing type information that identifies a correct locking nut drive up angle on at least one display of the computing device.
 8. A system for measuring angle adjustment of a hookspanner wrench to accurately tighten a bearing onto a shaft having a threaded and tapered portion, the system comprising: a device providing a hookspanner wrench having a lever arm and an engaging portion, the engaging portion of the hookspanner wrench configured to engage a bearing locking nut, a storage clamping device comprising a clamp, the storage clamping device being positioned on the lever arm, a smartphone secured in place by the clamp of the storage clamping device, a specialized application stored on the smartphone that provides a built-in inclinometer and look up data tables, the bearing having an inner race and a tapered bore being mounted over an outer unthreaded portion of the shaft, the bearing locking nut having a threaded inner portion and screwed onto a threaded portion of the shaft, the bearing locking nut screwed onto the threaded portion of the shaft until an inner side of the locking nut and an outer side of the bearing inner race contact each other, an interlocking arrangement providing a meshing grip between the hookspanner wrench and the locking nut, information regarding a type of bearing to be secured being entered into the smartphone, and wherein in response, a correct mounting angle/drive up position of the lock nut is displayed on the built-in inclinometer, a force F applied to the lever portion of the hookspanner wrench causes the hookspanner wrench to rotate while the mounting angle/drive up position is monitored against what is displayed on the inclinometer and wherein the application of force to the lever portion is stopped when the correct mounting angle/drive up position is indicated as being obtained on the inclinometer.
 9. The system for measuring angle adjustment of a hookspanner wrench to accurately secure a bearing onto a shaft according to claim 8, wherein the contact between an inner side of the locking nut and an outer side of the bearing inner race is a metal to metal contact.
 10. A method of measuring angle adjustment of a hookspanner wrench to accurately secure a bearing onto a shaft, the shaft having a threaded and tapered portion, the method comprising: sliding the bearing onto the tapered portion of the shaft, screwing a lock nut onto the threaded portion of the shaft until an inner side of the locking nut and an outer side of the bearing inner race contact each other, removing the locking nut off of the threaded portion, placing a spacer over the threaded portion of the shaft and up against the bearing, placing a lock washer over the threaded portion of the shaft and up against the spacer, attaching the hookspanner wrench onto the locking nut, providing a mounting device for a portable computing device disposed on a lever portion of the hookspanner wrench, attaching the portable computing device onto the mounting device, the computing device having a software application that includes a built-in inclinometer, initializing the software application that includes the built-in inclinometer, inputting identifying information into a display disposed on the computing device regarding a bearing type to be tightened, displaying a correct mounting angle/drive up position of the component on the built-in inclinometer, applying force to the lever portion and rotating the hookspanner wrench while simultaneously monitoring the mounting angle/drive up position displayed on the inclinometer, and stopping the application of force to the lever portion when the correct mounting angle/drive up position is indicated as being obtained on the inclinometer.
 11. A device for tightening a bearing onto a shaft, the device comprising: a hookspanner wrench comprising: an engaging portion configured to engage a locking nut of the bearing, a lever arm which extends radially away from the engaging portion, and a storage clamping device attached to the lever arm of the hookspanner wrench, the storage clamping device configured to hold a smartphone comprising a front surface with a user interface thereon, a rear surface, a bottom end, and a top end, the storage clamping device comprising: a first clamp end configured to abut the bottom end of the smartphone, a lateral wall extending from the first clamp end and configured to abut the rear surface of the smart phone, and a second clamp end slidably connected to the lateral wall and configured to abut the top end of the smartphone, the position of the first clamp end relative to the second clamp end being adjustable to facilitate clamping after the smartphone is positioned against the first clamp end and against the lateral wall to secure the smartphone in place.
 12. A system for tightening a bearing onto a shaft, comprising: the device of claim 11, and the smartphone positioned in the clamp, an application stored on the smartphone that provides a built-in inclinometer and look up data tables.
 13. The system of claim 12, wherein the look up data tables display a correct locking nut drive up angle based on a bearing type inputted into the smartphone.
 14. The system of claim 13, wherein when a force is applied to an outer end of the lever arm and the hookspanner wrench begins to rotate the locking nut, and wherein the inclinometer responds in real time and displays an updated locking nut drive up angle position.
 15. The system of claim 14, wherein the application of force applied to the lever arm is stopped when the correct mounting angle/drive up position is indicated as being obtained on the inclinometer.
 16. The system of claim 12, wherein one of an angle, a number, and a color is displayed on the inclinometer to indicate the mounting angle/drive up position has been obtained.
 17. The system of claim 12, wherein the user interface further comprises a Full Qwerty Keypad for entering bearing type information that identifies a correct locking nut drive up angle on at least one display of the computing device. 